Pneumatic motor



Feb. 22, 1966 N c, w| ETAL Re. 25,964

PNEUMATIC MOTOR Original Filed April 19. 1962 2 Sheets-$heet 1 Fig". 4. Fig. 5.

INVENTORS Norman Cwillioms Harry E Everefi ATTYS.

Feb. 22, 1966 N. c. WILLIAMS ETAL Re. 25,964

PNEUMATIC MOTOR 2 Sheets-Sheet 2 Original Filed April 19, 1962 ATTYS United States Patent Ofiiice Reissued Feb. 22, 1966 25,964 PNEUMATIC MOTOR Norman C. Williams and Harry F. Everett, Portland, Oreg., assignors to Power Brake Equipment Company, Portland, Oreg., a corporation of Oregon Original No. 3,088,707, dated May 7, 1963, Ser. No. 188,745, Apr. 19, 1962. Application for reissue Nov. 16, 1964, Ser. No. 427,525

19 Claims. (Cl. 2532) Matter enclosed in heavy brackets appears in the original patent but forms no part of this reissue specification; matter printed in italics indicates the additions made by reissue.

This application is a continuation-in-part of US. patent application, S.N. 134,493, filed August 28, 1961, by the present joint inventors, Norman C. Williams and Harry F. Everett on their invention of a Pneumatic Motor of which this invention is an improvement.

It is a primary object of this invention to provide a pneumatic motor of high speed and small size particularly adapted to the quiet and precise operation of a dental handpiece.

It is a second object to provide such a pneumatic motor having operating elements of such simplicity that, where desired, the same motor design can be enlarged for construction of larger motors.

It is a third object to provide such a motor having a rotor with an axle on a central axis and a pneumatic turbine wheel secured coaxially on said axle at about the midlength thereof.

It is a fourth object to provide such a motor with such a rotor having a pair of axle cones secured on said axle, one near each end thereof spaced from opposite ends of said wheel and the conical surfaces of said axle cones expanding along said axle from their inner ends near said wheel.

It is a fifth object to provide such a motor with a stator having a generally cylindrical open ended casing including a handle boss formed on one side of said casing near its midlength and normal to the axis of said rotor and said casing, said boss including a high air pressure manifold formed therein and said casing including a pair of end caps removably secured over the ends thereof.

It is a sixth object to provide such a motor with such a stator having a pair of hollow conical bearings, one at each end of said stator to mate with and support said rotor on said axle cones thereof.

It is a seventh object to provide such a motor with such a stator in which each of said bearings is formed with an annular high pressure air manifold around the outside thereof and a plurality of spaced .air jet holes from said manifold through said bearing to the high pressure air gap of capillary thickness between said conical stator bearing and its mating axle cone.

It is an eighth object to provide for each of said stator bearings 21 pair of novel and useful seal ring means resiliently to seal the outside of the stator bearing to the inside of the stator casing above and below said annular .air manifold whereby said mating axle cone of said rotor will be positioned with respect to the stator bearing cone by the resilience of said seal rings, the pressure of air in said manifold and the capillary thickness of the air gap between the conical bcaring and the axle cone.

It is a ninth object to provide said turbine wheel of said rotor with a plurality of spaced parallel blades normal to the axis of said rotor, said blades including a plurality of exhaust holes formed through said blades near to and parallel the axis of said wheel and a plurality of spaced notches in the periphery of said wheel to provide an improved grip on said wheel of the high pressure air ejected thereagainst.

It is a tenth object of this invention to provide in the handle boss of said casing of said motor a nozzle conduit from the high pressure air manifold of said boss to the interior of said casing directed parallel to a tangent to the surface of said wheel but below the surface thereof and to provide for each of the air pressure manifolds of each of said bearing cones a separate nozzle conduit from said manifold in said handle boss to the inner surface of said casing opening into said manifold back of said bearing cone.

How these and other objects are attained is explained in the following specification referring to the attached drawing in which FIG. 1 shows a dental handpiece, for which the pneumatic motor of this invention is particularly preferred, in side elevation and in approximately its actual size.

FIG. 2 shows a fragment-ally enlarged annular top plan view of the handpiece as seen from the plane marked 22 of FIG. 1.

FIG. 3 is a fragmentary side sectional elevation as viewed along the center plane 33 of FIG. 2.

FIG. 4 is a fragmentary plan section as seen downwardly from the plane 44 of FIG. 3.

FIG. 5 is a fragmentary plan section as seen downwardly from the plane 55 of FIG. 3.

FIG. 6 is a vertical sectional elevation viewed from the offset plane 66 of FIG. 3.

Like numerals refer to like parts in the several figures of the drawing.

Referring now to the several figures of the drawing; the stator of the pneumatic motor M of this invention is seen in FIG. 3 to include a generally open ended cylindrical casing C formed with a generally cylindrical handle boss H cast on to said casing to extend therefrom about midlength of said casing and axially normal to the axis of said casing. Near each of its ends the inside diameter of casing C is increased to allow the placement therein of flat annular stop rings 21, 22. A pair of end caps 33 and 34 are threadedly secured over the respective ends of casing C. Within either end of the casing C and on end cover 33 or 34 is a hollow stator bearing cone, 27 or 28, formed to fit and be supported in a bearing ring 25 or 26 whereby either of the bearing cones 27 or 28 combined with its bearing ring 25 or 26 forms a stator bearing 0r bearing assembly 29 or 30.

A particular feature of this invention is the novel design and particular use of the seal rings 23, 23s, 24, 24s, each formed at its larger diameter with a metal wire 31, approximately square in section, over which a rela tively stiff rubber-like material 32, is molded securely thereto to form a short cone converging axially inwardly from its wired end.

Note that in assembling a stator bearing 29 or 30, into the casing C, a stop ring 21 or 22 is first assembled into the casing C against the casing step 21s or 22s and then a [real] seal ring 23 or 24 is placed on the stop ring 21 or 22 with the metal ring end of seal ring 23 or 24 against the stop ring 21 or 22. The bearing ring assembly 29 or 30 is then placed in position on the seal ring 23 or 24 and the second seal ring 23s or 24s is placed with its softer ends against the appropriate bearing assembly 29, 30. It is seen in FIG. 3 that by applying a spanner wrench to the appropriate holes 35, 36 of cover caps 33, 34 the seal rings 23, 24 of either end bearing can be positioned not only to seal the bearing air manifold spaces 37, 38, but also to provide a desired rocking stiffness to the seal ring assemblies supporting the end bearing assemblies 243l].

Now referring to the rotor R of the pneumatic motor M of this invention, the rotor is seen in FIG. 3 to comprise a quill bolt 40 or rotor axle formed with an axial hole therethrough, said hole being enlarged and threaded from its head end a greater portion of its length to receive a relatively stiff externally threaded hollow chuck 41 for a dental drill or burr 78. Since the bolt 40 has an axial hole throughout its length a drill or burr can be ejected from chuck 41 by tapping a blunt needle of small diameter into the hole against the blunt end of the drill 78. The end of quill bolt 40 opposite its head is threaded to receive a lock nut 42 for secure assembly on said bolt of a pair of oppositely tapered, axially spaced, spindle cones 43, 44, a turbine wheel 62 and a plurality of shim leaves 46 as required to position spindle cones r rotor journals 43, 44 of the rotor in axial spacing agreement with the bearing cones 29, 30 of the stator to avoid contact of the conical surfaces across the conical capillary spaces or gaps 47, 48 at opposite ends of the motor.

Note in FIGURES l, 3 and 6 that there is no metallic connection between handle boss H of motor casing C and the handpiece 50 through which operating air is supplied to the mechanism. Between surface offset 52 of boss H and its end rabbet 53, boss H is heavily coated with a rubber polymer and heated to be in a mastic condition. Then the adjacent end of handpiec-e 50 is pushed over boss H without metallic contact therewith and the temperature of the joint is raised sufficiently for a sufficient time to polymerize the material in the joint and the joint condition will be permanently without metal to metal contact between handle boss H and handle 50. This disclosed method of suppressing the development of sonic vibration in the system is a novel and desirable feature thereof.

Note also that handle boss H of casing C is axially bored from its outer end inwardly to about the midlength of its neck, 60, and an air conduit coupling tube 54 is inserted into the bore of boss H to seal therein the high pressure air manifold 55 fed high pressure air from a source there of through coupling tube 54 [connected to conduit tube 55], the coupling tube entering handle 50 through its end opposite boss H.

Lower pressure air and water tubes [56] 56' and [57] 57' enter the inlet end of handpiece 50 and therein are connected with metallic nozzle tubes 56 and 57 after which nozzle tubes 5657 are together brought out from the interior of handle 50 and supported thereon by band 77 free of contact with handle boss H of casing C. It is again noted that there are no metallic contacts between any parts of motor M and handle 50.

Now considering the high pressure air power supply to the improved pneumatic motor M of this invention it should first be noted that the two upper and lower stator bearing supporting high pressure air manifolds, 37 and 38, respectively, are fairly large in volume. Equally spaced around each of them are a plurality of radially inwardly projecting air jets 58, each projecting its supply of rotor supporting high pressure air from its manifold 37 or 38 through its individual expansion chamber 59 at a somewhat reduced velocity but equally increased pressure into the conical capillary gap spaces 47 or 48 separating the stator bearing cones 29, 30 from the spindle cones 43, 44 of the rotor R of motor M.

Side pressure on the end of a Working drill or burr extending from the chuck 41 of the rotor R will tend to cock the axis of the rotor with respect to the axis of the stator and angular movement of the roior cause the same angular movement of the spindle cones 43, 44 and have a tendency to take the stator bearing cones therewith. However when this tendency occurs the value of the yielding mounting of the stator bearing assemblies 29, 30 in the seal rings 23, 24 is shown for then the seal rings 23, 24 allow the bearing assemblies to move either laterally or longitudinally the infinitesimal amount required to recenter the bearing journals of the rotor on the axis of the siator bearing assemblies there will be no solid material contact either laterally or longitudinally of stationary to rotary parts.

Continuing with respect to the rotor R of the motor M as seen in FIGURES 3 and 4, the rotor axle or headed quill bolt 40 is internally threaded from its head end to receive the externally threaded nonmetallic chuck 41 for a dental drill or burr 78 [not shown]. Bolt [41] 40 is externally threaded at its other end to receive lock nut 42 for the purpose of axially securing on said bolt the turbine wheel 62 of rotor R and upper and lower spindle cones 43, 44 of said rotor. Each of said cones have cylindrical extensions 65 or 66 at their inner ends which together with variable stack of shim leaves 46 are used to space rotor bearing journals 43, 44 from wheel 62 to form exhaust air spaces 68, 69 and also to space rotor bearing journals 43, 44 from stator bearing assemblies 29, 30, to determine the conical capillary spaces 47, 48 between the rotor bearing journals 43, 44 and the conical stator bearing assemblies 29, 30. It is seen that the high pressure bearing supporting air from manifold 55 in handle boss H of casing C discharges air through conduits [37] 37', [38] 38 to stator manifolds 37, 38 and then to capillary spaces 47, 48 through jets 58 and quieting spaces 59 and must discharge to atmosphere through the large diameter ends of spaces 47, 48 into the spaces 70, 71 under the siator end caps 33 and 34 and out to atmosphere through holes 72, 73 in the end caps and through the small diameter ends of spaces 47, 48 into the exhaust spaces 68, 69 from where this low pressure exhaust air is exhausted to the interior of handle through conduits [68] 68', [69] 69. The exhaust air from spaces 68, 69 and conduits [68] 68, [69] 69' to the interior of handle 50 can be exhausted from handle 50 directly to atmosphere or can be taken farther away with an exhaust hose, not shown.

Referring now to the improved turbine wheel 62 as seen in FIGURES 3 and 4 where the scale is approximately 6 to 8 times size, the wheel is made of a circular disk of stainless steel less than one-eighth inch thick and less than three-eighths inch in outside diameter. The inside diameter of wheel 62 is a neat fit over the outside of bolt 40. Centered in plane 44 of FIG. 3 and angled like the conduit 51 shown in FIG. 4, the five spaced notches 51s are next bored with a circular tool into the edge of block 62 as shown at 5121 in FIG. 3. Next five pairs of holes 51b, spaced as shown in FIG. 4 are drilled through block 62 substantially tangent to the circular extension 65, 66 of spindle cones 43, 44 in the axial directions thereof. And finally, a plurality of parallel capillary slots 62s are sawed into block 62 from its outer perimeter to the inner edges of holes 51b.

This construction of turbine wheel 62 is an effective improvement in the pneumatic motor of this invention since the high pressure air through nozzle conduit 51 from manifold strikes into the periphery of wheel 62 in the direction normal to the shorter sides of spaced notches 51s whereby a greater amount of active air is pressured into capillary slots 62s on its way through the slots and upwardly or downwardly out the exhaust holes 51b to exhaust 68, 69 to escape therefrom by conduits 68, 69 to the outer interior of handle 50. Note also that by the direction of air driven into slots 515 from nozzle conduit 51 additional work is obtained from the air because of its high speed direction of tangency to the exhaust holes 51b and the delay of the air in getting to the exhaust holes 51b.

Having here recited some of the principal objects of our invention, illustrated and described a preferred way in which our invention may be practiced, and described its operation, we claim:

[1. A dental handpiece for driving a dental drill at high speed, said handpiece having a stationary casing, a rotor including an axle supported coaxially in said casing, a compressed air driven turbine wheel secured coaxially on said axle for driving said rotor, a pair of outwardly facing oppositely conical rotor bearing journals secured on said axle at its opposite ends, a pair of inwardly facing oppositely conical stator bearing assemblies each including a supporting ring surrounding one of said stator bearings on its outer side to make up said assemblies, each of said supporting rings having a groove sunk circumferentially therearound adjacent to the inner face of said casing, said casing including on either axial side of each of said grooves a pair of identical conical resilient seal rings for sealing and supporting said conical stator bearing assemblies resiliently on the inner face of said casing to provide an inlet manifold for compressed air, each of said inner faced conical stator bearing assemblies including conduit means for connecting its said groove with the conical air gap between said inner faced conical stator bearing assembly and its mating outwardly facing rotor bearing journal] [2. The dental handpiece of claim 1, in which said rotor extends substantially the length of said casing, said turbine wheel is secured at substantially the mid-length of said axle, and said rotor bearing journals comprise conical surfaces axially spaced from opposite sides of said wheel and radially increasing toward the ends of said axles] [3. The dental handpiece of claim 1 in which said casing includes a nozzle conduit formed therein for supplying compressed air substantially tangentially to said wheel in a plane normal to the axle thereof] [4. The dental handpiece of claim 3 in which said turbine wheel comprises a disc having a plurality of axially spaced circumferential capillary slots, a plurality of uniformly circumferentially spaced axially extending notches, and a plurality of axial exhaust holes near the axis of said disc and providing communication between said slots and a pair of exhaust spaces disposed between said wheel and said stator bearing assemblies, and said stationary casing having a plurality of exhaust conduits leading from said exhaust spaces to the atmosphere] 5. A pneumatic motor comprising a stator and a rotor, said stator including a generally cylindrical open ended casing, a handle boss secured to one side of said casing, a pair of end caps axially adjustably secured over the respective ends of. said casing, said boss including means forming a first space for receiving and storing high pressure pneumatic fluid, said motor including a source of said fluid under pressure, said rotor including an axle concentric with said casing and about the length of said casing with its end caps, said axle including a pneumatic turbine wheel secured coaxially thereon at about its midlength, said axle including, near its ends and spaced from the opposite faces of said wheel, a pair of conical journals axially adjustably secured on said axle with the conical outer surfaces thereof starting near said wheel and expanding therefrom toward the ends of said axle, said casing including a nozzle conduit formed therein for receiving said pneumatic fluid from said first space, and dis charging said pneumatic fluid received from said first space through said nozzle conduit against the surface of said wheel in a vertical angular direction substantially normal to said wheel and in a horizontally angular direction substantially within a line of tangency to the circumference of said wheel, said stator including, one near each end of said casing, a pair of hollow inwardly facing conical stator bearings together with a supporting ring for each of said stator bearings to form therewith a pair of conical stator bearing assemblies, each of said assemblies on its outer circumferential face near the inner face of said casing having sunk therearound a circumferential groove and said stator including on opposite sides of each of said grooves a pair of substantially identical resilient seal rings for sealing said one of said conical stator bearing assemblies on either side of said groove to the inner face of said casing, thereby to form with said grooved assemblies, said casing and said pairs of resilient rings, respective second and third spaces for high pressure pneumatic fluid.

6. The pneumatic motor of claim 5 in which said casing includes second and third high pressure pneumatic fluid conduits connecting said first space for high pressure pneumatic fluid with said grooves in said conical stator bearing assemblies to form thereby inlet manifolds of said grooves and each of said grooves in said bearing assemblies is formed with a plurality of circumferentially spaced radial jet means each discharging high pressure pneumatic fluid through one of a plurality of high pressure fluid expanding spaces formed through the adjacent conical stator bearing assembly into one of said gaps for high pressure pneumatic fluid between the opposing faces of said rotor bearing journals and the inner faces of said stator bearing assemblies to support said rotor axle journals on the high pressure pneumatic fluid between said rotor journals and said stator bearing assemblies.

7. The pneumatic motor of claim 5 in which said pair of seal rings are substantially conical but approximately rhomoboidal in section with the larger diameter thereof against the inner diameter of said stator casing and reinforced at its larger diameter of said section with a continuous metal ring small and approximately square in section to prevent deformation of said seal ring as it is held in place between said stator bearing assembly and an inner face of said casing, the remaining inwardly converging axial length of said seal ring being formed of a rubber-like relatively rigid material to maintain a seal against the outside surface of said grooved supporting ring of said stator bearing assembly and give said supporting ring a sealing strut support stress between said casing and said stator bearing assembly, whereby said stator bearing assembly can yieldingly resist any eccentric movement of said high pressure air supported rotor axle to maintain said axle in its concentric position.

8. In a pneumatic motor, an axle; a pair of conical rotor journal elements disposed on said axle facing 0pposite directions on the axle, and coaxial therewith; a pair of stator bearing elements surrounding said rotor journal elements, one mating with cach rotor journal element; each stator bearing element having an inner circumferential air bearing defining surface extending thereabout, and the rotor journal element mating therewith having an outer circumferential air bearing defining surface which with the surface of the stator bearing clement defines an annular cupillw'y space for receiving air which is coaxial with said axle; a casing; menus securing said pair of stator bearing elements n the casing; and means securing said pair of rotor journal elements on the axle; one of said means accommodating relative axial adjustment in the position of the pair of elements secured thereby, thus to change the size of the capillary spaces defined by the pair of elements with the other of said pair of elements.

9. A pneumatic motor comprising an axle; a pair of conical rotor journals disposed on the axle at points spaced axially thcrealong; a power-driven turbine wheel secured coaxially on Said axle between said rotor journals; said rotor journals being concentric with and having small diameter ends facing toward each other on the axle; a pair of stator bearings surrounding said rotor journals, one mating with each rotor journal; each of said stator bearings having an inner circumferential air hearing defining surface, and the rotor journal mating therewith huving an outer circumferential air hearing defining surface within said first-mentioned air bearing defining surface, and the two surfaces together defining an annular capillary space for receiving air which is coaxial with said axle; conduit means in each stator bearing communieating with the capillary space that it defines for the admission of air t the space, thus to produce a pressure of air within the space; a casing; resilient means mounting each stator bearing on the casing whereby the rotor journals within the bearings are supported both by air in said capillary spaces and by said resilient means; and means securing the rotor journals on said axle accommodating relative axle shifting of the journals thus to change the size of the capillary spaces.

10. A pneumatic motor comprising an axle; a pair of conical rotor journals having small and large diameter ends joined to said axle at points spaced axially therealong and with the rotor journals concentric; a pair of conical stator bearings surrounding said rotor journals, one mating with each rotor journal; each of said stator bearings having an inner circumferential gas bearing defining surface and the rotor journal mating therewith having an outer circumferential gas bearing defining surface surrounded by the gas bearing defining surface of the stator bearing; said gas bearing defining surfaces of each mating rotor journal and stator bearing together defining an annular capillary space for receiving gas which is coaxial with said axle; conduit mean connecting with said capillary space for each mating rotor journal and stator bearing for the admission of gas thereto, to produce a pressure of gas within said capillary space; and a powerdriven turbine wheel secured coaxially on said axle between said rotor journals; said rotor journals having their said small diameter ends facing toward each other on said axle and adjacent said turbine wheel.

11. A pneumatic motor comprising a rotor including a power-driven axle; said rotor further including a pair of conical rotor journals having small and large diameter ends joined to said axle at points spaced axially therealong; said rotor journals being concentric and their small diameter ends facing in opposite directions on the axle; a pair of conical stator bearings surrounding said rotor journals, one mating with each rotor journal; each of said stator bearings having an inner circumferential air bearing defining surface and the rotor journal mating therewith having art outer circumferential air bearing defining surface surrounded by the air bearing defining surface of the stator bearing, and said air bearing defining surfaces of each mating rotor journal and stator bearing together defining an annular capillary space for receiving air which is coaxial with said axle; conduit means communicating with said capillary space for each mating rotor journal and stationary bearing for the admission of air to said space to produce a pressure of air within the space; a casing surrounding said pair of stator bearings; and a ring of resilient material coaxial with said rotor provided for each stator bearing, mounting the stator bearing on the casing; each of said rings having a hollow conical frustum shape and being flexible in radial and axial directions, and being operable to position the rotor within the casing with the rotor cushioned by the air within said capillary spaces and the rings of resilient material mounting the stator bearings; said rings facing opposite directions on said axle.

12. In a motor; a rotor including an axle; said rotor further including a wh el joined to said axle operated by power to produce rotation of said axle, and a rotor journal joined to said axle on each side of said wheel; a stator bearing for at least one of said rotor journals surrounding said rotor journal; said stator bearing having an inner circumferential gas bearing defining surface and said one rotor journal having an outer circumferential gas bearing defining surface surrounded by the first-mentioned gas bearing defining surface; said gas bearing defining surfaces together defining an annular capillary space for receiving gas with said s ace coaxial with said axle; conduit means communicating with said capillary space for the admission of gas thereto to produce a pressure f gas within such space; a casing; and resilient mounting means for the stator bearing mounting the stator bearing in the casing; said resilient mounting means comprising a pair of resilient rings to one side of said wheel spaced axially on the stator bearing with one set of peripheral margins supu ported on the casing and an opposite set of peripheral margins supported on the stator bearing; said rings being coaxial with said axle and bounding between them an .anular space for gas which communicates with the conduit means communicating with said capillary space.

13. A dental handpiece for driving a dental drill at high speed; said handpiece having a casing; a rotor including an axle supported in said casing; said rotor further including a compressed air-driven turbine wheel secured coaxially on said axle for driving said rotor and a pair of conical rotor journals coaxial with and secured on said axle, one on each side of said turbine wheel, with small diameter ends facing opposite ends of the axle; a pair of stator bearings within the casing, one mating with and surrounding one rotor journal and the other mating with and surrounding the other rotor journal; a pair of axially spaced apart resilient rings for each stator bearing mounting the stator bearing in said casing and d fining an annular space between them; each of said stator bearings having an inner circumferential surface that cooperates With its mating rotor journal to define a conical air gap; and conduit means in each stator bearing contmunicating at one end with the air gap defined by the in- .ner circumferential surface of the stator bearing and communicating at its opposite end with the annular space between the resilient rings that mount the stator bearing.

14. In a motor; a rotor including an axle and a conical rotor journal joined to said axle; a conical stator bearing surrounding said rotor journal; said stator bearing having an inner circumferential gas bearing defining surface and the rotor journal having an outer circumferential gas bearing defining surface surrounded by the first-mentioned gas bearing defining surface; said gas bearing defining surfaces together bounding an annular capillary space of conical outline for receiving gas with said space coxial with said axle; conduit means communicating with said capillary space for the admission of gas thereto to produce a pressure of gas within said space; a casing; and resilient mounting means mounting the stator bearing in the casing; said resilient means comprising a pair of resilient rings spaced axially on the stator bearing with one set of peripheral margins supported on the casing; said rings being coaxial with said axle and bounding between them an annular space for gas connected to said conduit means which communicates with said capillary space; each of said rings having a hollow cortical frustum shape and the two rings facing opposite directions on said axle.

15. In a pneumatic motor including a casing and an axle having an air-driven wheel mounted thereon, means on each side of said turbine wheel mounting the axle in said casing comprising a rotor journal joined to the axle and a stator bearing surrounding said rotor journal, said rotor journal and stator bearing having complementing circumferential gas bearing defining surfaces bounding an annular capillary space for receiving gas with said space coaxial with the axle; conduit means communicating with said capillary space for the admission of gas thereto to produce a pressure of gas within the space, and a pair of resilient rings spaced axially on the stator bearing with one set of peripheral margins supported on the casing and an opposite set of peripheral margins supported on the stator bearing, said rings bounding between them an annular space for gas and said annular space connecting with said conduit means which communicates with said capillary space.

16. Ina motor comprising a casing and a rotor mounted within the casing; said rotor including an axle and driving means joined to the axle operated by power to produce rotation of the axle; gas bearing structure disposed to one side of said driving means mounting said axle within the casing; said gas bearing structure comprising a conical rotor journal joined to the axle and a conical stator bearing surrounding the rotor journal mating with the rotor journal, said rotor journal and stator bearing having a complementary circumferential gas bearing defining surfaces which together bound an annular capillary space of conical outline which is coaxial with the axle for containing gas with such gas distributed as a supporting film for the rotor journal within said capillary space; conduit means connecting with said capillary space for the admission of gas thereto; and resilient means mounting said gas bearing structure on said casing operable to provide a dampening action in both axial and radial directions compensating for the nondampenable characteristics of a gas-supporting film; the gas-supporting film within said space having a nondampenable characteristic in both axial and radial directions because of the conical outline of the capillary space containing the film and said resilient means having flexibility in both radial and axial directions to produce a compensating dampening in both of such directions.

17. In a motor; a power-driven axle and rotor journal structure comprising a pair of rotor journals joined to the axle at points spaced axially therealong; stator bearing structure comprising a pair of stator bearings surrounding the rotor journals and supporting them; a casing surrounding the stator bearing structure; and at least a pair of rings of resilient material mounting the stator bearing structure on said casing with the axle and said rotor journals being cushioned in said casing through the rings of resilient material mounting said bearing structure; said rings of resilient material having hollow conical frustum shapes and facing opposite directions on said axle, with one set of peripheral margins on the casing and another set of peripheral margins on the stator bearing structure.

18. In a motor; a rotor including an axle and a rotor journal joined to said axle; a stator bearing surrounding said rotor journal; said stator bearing having an inner circumferential gas bearing defining surface and said rotor journal having an outer circumferential gas bearing defining surface, and said gas bearing defining surfaces together bounding an annular capillary space for receiving gas which space is coaxial with said axle and surrounds the rotor journal; means communicating with said capillary space for the introduction of gas thereinto to produce a pressure of gas within said space,- a casing; and resilient means mounting the stator bearing in the casing accommodating movement of the stator bearing relative to the casing; said resilient means having a construction permitting movement of the stator bearing relative to the casing in all directions extending radially of said rotor journal; said resilient means, on m vement of the rotor journal in a given radial direction within said capillary space whereby one side of the rotor journal moves toward a side of the stator bearing permitting the stator bearing to move in the same direction whereby any reduction in thickness in the capillary space on said one side of the rotor journal is less than that which would occur were the stator bearing stationary and any increase in thickness of the capillary space on the opposite side of the rotor journal is less than that which would occur were the stator bearing stationary. 19. In a motor; a rotator including an axle and a rotor journal joined to said axle,- a stator bearing surrounding said rotor journal; said stator bearing having an inner circumferential gas 10 bearing defining surface and said rotor journal having an outer circumferential gas bearing defining surface, and said gas bearing defining surfaces together bounding an annular capillary space for receiving gas which space is coaxial with said axle and surrounds the rotor journal;

means communicating with said capillary space for the introduction of gas thereinto to produce a pressure of gas within said space;

a casing; and

a resilient ring surrounding the stator bearing mounting the stator bearing in the casing accommodating movement of the stator bearing relative to the casing in all directions extending radially of the rotor journal; said resilient ring, on movement of the rotor journal in a given radial direction within said capillary space whereby one side of the rotor journal moves toward a side of the stator bearing permitting the stator bearing to move in the same direction whereby any reduction in thickness in the capillary space on said one side of the rotor journal is less than that which would occur were the stator bearing stationary and any increase in thickness of the capillary space on the opposite side of the rotor journal is less than that which would occur were the stator bearing stati nary.

20. A dental handpiece for driving a dental drill at high speed, said handpiece having a stationary casing, a rotor including an axle supported coaxially in said casing, said rotor further including a compressed air driven turbine wheel secured coaxially on said axle for driving said rotor and a pair of outwardly facing oppositely conical rotor bearing journals secureld on said axle at its opposite ends, a pair of inwardly facing oppositely conical stator bearing assemblies mating with the rotor bearing journals to define conical air gaps therewith, each of said stator bearing assemblies including a supporting ring surrounding the stator bearing assembly on its outer side to make up said assembly, each of said supporting rings having a groove sunk circumferential/y therearound adjacent to the inner face of said casing, said casing including on either axial side of each of said grooves a pair of conical resilient seal rings for sealing and supporting said conical stator bearing assemblies resiliently on said casing to provide an inlet manifold for compressed air, each of said inwardly facing conical stator bearing assemblies including conduit means for connecting its said groove with the conical air gap between the bearing assembly and its mating outwardly facing rotor bearing journal.

21. The dental handpiece of claim 20 in which said rotor extends substantially the length of said casing, said turbine wheel is secured at substantially the mid-length of said axle, and said rotor bearing journals comprise conical surfaces axially spaced from opposite sides of said wheel and radially increasing in size progressing toward the ends of said axle.

22. The dental handpiece of claim 20 in which said casing includes a nozzle conduit formed therein for sup plying compressed air substantially tangentially to said wheel in a plane normal to the axis thereof.

23. The dental handpiece of claim 22 in which said turbine wheel comprises a disc having a plurality of axially spaced circumferential capillary slots, a plurality of uniform ly circumferential/y spaced axially extending notches, a plurality of axial exhaust holes near the axis of said disc and providing communication between said slots, a pair of exhaust spaces are disposed between said wheel and said stator bearing assemblies, and said stationary casing has a plurality of exhaust conduits leading from said exhaust spaces to the atmosphere.

(References on following page) 1 1 References Cited by the Examiner 2,897,596 The following references, cited by the Examiner, are 311341172 of record in the patented file of this patent or the original 3'147551 patent. 5

UNITED STATES PATENTS 1,236,409 1,047,898 12/1912 Scott. 1,099,693 2,471,812 5/1949 Christiano 230-232 847,331 2,602,632 7/1952 Serduke et al. 354,893 2,605,619 8/1952 Serduke 253 2,871,562 2/1959 Kern. 2,895,738 7/1959 Baker 2532 12 10/ 1959 Maurer.

5/ 1964 Sato.

9/1964 Scegers 253-3 FOREIGN PATENTS 6/ 1960 France.

2/ 1961 Germany. 9/1960 Great Britain. 7/ 1961 Switzerland.

*3 w SAMUEL LEVINE, Primary Examiner.

HENRY F. RADUAZO, Examiner. 

